Pipe and casing tongs



May 26, 1953 F. E. SMITH 2,639,894

' PIPE AND CASING TONGS Filed Nov. 17, 1951 6 Sheets-Sheet 1 T0 COMP.

. INVENTOR. FRED E. SMITH ATTORNEYS May 26, 1953 F. E. SMITH PIPE AND CASING TONGS Filed Nov. 17, 1951 6'*sh98 iS-Sheet 2 INVENTOR.

FRED-E. SMITH @U-Luit A TTOR'NE Y6 y 26, 1953 I F. E. SMITH 2,639,894

Pfifi ANDTCASING TONGS INVEN TOR. FRED JM/ TH- BY A T TO ENE Y5 May 26, 1953 F. E. SMITH PIPE AND CASING TONGS I Filed Nov. 17, 1951 SERVOIR I23 m 26 '28 m F156 5 on --l r 12.7 Izag 206 3 :30 491 :22 20s I 130 m 132 g3: 9 I90 I56 74 m I56 l J 1 m J i J J 157 I83 I82 I35 l8 RETUQN on. FROMZ PRESSURE OIL PRESSURE 9 on. 1'0 *1 FHE0JMITH A TTORNE YJ May 26, 1953' F. E. SMITH; 2,

PIPE AND CASING TONGS Filed -7, 1951 I 6' Sheets-Sheet 5 MOTOR o TO WHISILE FROM AIR COMPRESSOR 92 9, 89 a INVENTOR. FREDESM/TH 19 8s 5"-& 85 9 I3 76 75 94 9.5" 33 j. v ATTORNEYS Patented May 26, 1953 Application November 17, 1951, Serial No. 256,940

(Cl.v 255--35) 12 Claims.

This invention relates to a power wrench for making and breaking joints of pipe such, for example, as drill pipe, casing, tubing and the like used in oil wells.

Many devices have been developed for holding a lower section of pipe having an internally threaded upper end and for threading thereinto 01- removing therefrom an upperv section of pipe having an externally threaded end. In drill stems, to which the present invention is most important, the internally threaded member constitutes the box end of a tooljoint and the externally threaded part constitutes the pin end of the joint. It is conventional in the oil well drilling art, and most logical when making up a threaded joint, to rapidly rotate the pin for the initial or greater portion of the thread engagement and then to apply controlled force to the pin for the last portion of the engaging turns to set it solidly in the box. The rapid rotation of the pin is referred to as spinning. The reverse of the above is used for breaking out or unscrewing the drill pipe.

The final tightening of the pin in the box must be carefully controlled in order to prevent damage to the threads of the two pipe sections or overexpansion of the box which readily occurs when the pipes are threaded together with excessive force. However, it also is necessary to apply considerable force because the joints must be tight enough to prevent their inadvertently becoming loose or unscrewing during drilling operations or when the string is being pulled or reinserted in the well.

Mechanisms for accomplishing this purpose have been designed in the past but frequently such prior art mechanisms are not provided with sufiiciently sensitive controls to properly set and control the force with which the final tightening is accomplished and thus many prior art mechanisms damage both the pins and boxes during the tightening step. At present joints of this type are made up byuse of a cat head'towhicha. spinning line is attached. The taut moving line. constitutes a decided hazard to the men engaged. in the operation audit is not uncommon for a' man to become entangled in-theline and suffer severe injury. Such hazard is completely eliminatedv by the present invention.

It is the principal object of this invention to provide a power driven wrench for assembling sections of drill pipe, casing or tubing pipes, which is provided. with mechanism for holding a box and spinning a pin thereinto and for applying controlled, almost purelytorque-like force, to the pin for tightening the joints or initiating a break. v

It is a further object of this invention toprovide such a mechanism having simple fool-proof controls and provided with safety features that prevent the operation of the power means unless and until the various elements of the mechanism are properly positioned and both the box and pin are securely held in the mechanism. I

It is yet another object of this invention to provide a wrench for assembling and disas sembling strings of drill pipe, casing or tubing pipe which can easily be moved out of the way when not in use and which is provided with simple manually actuated, interchangeable means for grasping pins and boxes of different diameters and with simple control means for varying the force supplied in the tightening operation depending upon the diameter of the pin and box being threaded together.

More specific objects and advantages will be come apparent from the description which follows and from the drawings, in which:

Fig. l is an end view in elevation with parts broken away of a wrench embodying the invention.

I Fig. 2 is a plan view of the wrench shown in Fig. 1 and illustrating how the pin grasping elements are openable to permit insertion and removal of a pin being stabbed into a box.

Fig. 3 is a vertical sectional view with parts broken away taken substantially along the line 33 of Fig. 2.

Fig. 4 is a fragmentary horizontal sectional view taken substantially along the line 4-4 of Fig. 3.

Fig. 5 is a fragmentary vertical sectional view taken on the line 55 of Fig. 1.

Fig. 6 is a schematic view of a hydraulic system and the controls therefor for actuating a wrench embodying theinvention to tighten or loosen a pin in a box. I

Fig. '7 is'a detailed view in elevation taken from the position indicated by the line 7-1 of Fig. 6.

Fig. 8 is a schematic view similar to a portion of Fig. 6 but showing the hydraulic system valving means as set for rotating apin or moving the pin rotating portion of the wrench in a counterclockwise directionifor example, in Fig. 4).

Fig. 9 is a view similar to Fig. 8 but showing the valving mechanism in position to produce clockwise rotation.

Fig. 10 is an enlarged fragmentary detailed plan view with parts broken away showin the pin clamping means and a safety pneumatic circuit designed to prevent the spinning mechanism from being operated before the pin is securely grasped by the pin clamping means.

Fig. 11 is a fragmentary vertical sectional View taken substantially on the line H-H of Fig. 10. Fig. 12 is a detailed vertical sectional view taken substantially on the line l2--I2 of Fig. 10.

Fig. 13 is a fragmentary vertical sectional view taken on the line I3-l3 of Fig. 12.

Fig. 14 is a fragmentary view in front eleva-.

tion and on an enlarged scale of the valve control means with which a wrench embodying the invention is equipped and also illustrating certain safety and cutoif valve operating means.

Fig. is a vertical sectional view taken substantially'on the line I5I5 of Fig. 14.

Fig. 16 is a plan view of the mechanism shown in Fig. 14.

Clamping means A wrench embodying the invention may have a major housing generally indicated at it and provided with a lower clamping means 2| for tightly grasping a box 22 on the upper end of a tool joint or casing pipe 23 that extends downwardly through a well cover 25. The wrench also has an upper clamping means generally indicated at 25 for tightly grasping a pin end 26 of a second, upper section of pipe 2'?! which is either being threaded into or removed from the box 22 on the lower section of pipe 23.

The wrench is provided with a plurality of appropriately located eyes 28 to which supporting cables 29 are secured so that the wrench, as a whole, can be moved into and out of position for tightening or loosening joints. The wrench 28 also has a stabbing guide 3% which guides the pin 26 when it is to be stabbed into the box 22. The stabbing guide 30 is secured on the upper surface of the major housing 26).

The pin clamping means 25 (see Figs. 2 and 10) consists of a circular guideway 3| which comprises a semi-annular section 32 fixedly positioned in the housing 23 and two quadrants 33 and 3:2. Each of the quadrants 38 and 35 is supported on an arm 35 or 36, respectively, each of which is journalled in one of a pair of trunnions 3'! that are supported at the rear of the main housing 251 with thei vertical axes generally in line with the diameter of the circular guideway 3 4 along which the quadrants 33 and 3d are parted from the semi-annular section 32.

The quadrant 3t is provided with an over center locking means consisting in a bifurcated link 36 secured on a vertical hinge pin 39 that is studded into an ear it formed at the rear of the quadrant 3s. The bifurcated link 33 pivotally carries at its opposite end and on a pin 4 l, a hand locking lever 52 that is provided with a finger d3 which fits into a vertical notch 44 cut in an ear d5 located at the rear of the quadrant 33.

By referring to'Fig. 2 it can be seen that when the hand lever 42 is swung on the pin 4! in a clockwise direction its finger 43 is disengaged from the slot dd ear 45 and then the handle 62 and bifurcated link 38 can be swung on the pin 39 to release the two quadrants 3B and 3 allowing them to be swung on their trunnions it! into the position shown in broken lines in Fig. 2-and in Fig. 10. This opens the clampingmeans for the removal or insertion of a pin The lower or box clamping means 2| is construoted similarly to the upper clamping means 25, except that a se1ni-annular portion 3-5 (see Fig. 3) corresponding to the semi-annular section 32, is not merely a guideway, but directly retains and supports tong grips 4'1 and each of the two quadrants, for example, quadrant 48 (Fig. 1) and quadrant t9 (Fig. 3) similarly directly act upon the wrench grips 47. The clamping means 2! is provided with a hand actuated lever 58 pivotally connected to a bifurcated link 5| (Fig. 3) that in turn is pivoted on a pin 52 that extends through an ear 53 at the rear of the lower quadrant 49 for clamping the two lower quadrants E8 four segmental sets of plates 59, 69, iii and GE,

respectively. The pairs of plates 69 and (ii are spaced by pins 63, E i, 65 and 65, being linked to the plates 59 and 62 by the pins t3 and Ed, respectively. and to each other through the medium of a pair of toggle links 6? in which the pins and it are pivoted. A rocking pin 65 extends vertically between the two toggle links 5? and fits into a generally circular recess 68 formed in a rotatable semi-annular ring gear it. The ring gear it) rotates in ways ii and '52 (see Fig. 3) in the circular guideway 35.

As can best be seenin Fig. 10 the pins 63 and (it he along the parting diameter of the guideway ii at which the semi-annular portion 32 is separated from the quadrants 33 and 3 5 when they are swung outwardly on their trunnions 3i to open the clamping means 25. The pairs of plates 59 and 62 similarly open when the quadrants and it are opened.

The construction of the wrench ti (located in the lower clamping means 2|) is substantially identical with that of the upper wrench 5i except that the lower clamping means 2i does not include the ring gear it that is included in the upper clamping means 25.

The two spaced pairs of plates 59 and 62 which comprise the openable sections of the wrench 5'! are provided with engaging teeth l3, carried by the plates 55!, and teeth 15, carried by the plates 52. The teeth "l3 and "M overlap and engage when the pairs of plates 59 and 52 are swung inwardly to engage the grippers 53 with the exterior surface of the pin 25.

The ring gear it, in common with the guideway 3!, has a semi-annular section 15 corresponding to and associated with the semi-annular section 32 of the guideway ti and also has a pair or quadrant-like sections J5 and l? which correspond to and are associated with the quadrants 33 and 3d of the guideway 31. The ring gear '70 is provided with two sets of teeth forming a lower spur gear ill (Fig. 3) and an upper bevel gear 79 formed at the lower edge of the ring gear 79 and the upper outside corner thereof, re-- spectively.

The ring gear 10, including its semi-annular section 15 and its two quadrant-like sections 76 and 11, rotates as a unit in the guideway 31 when the semi-annular section 32 and two quadrants 33 and 34 are clamped together in closed position.

The quadrant-like sections 16 and 11 of the ring gear 10 are provided with correspondingly shaped lips as (see Figs. 3 and 10) which support a plurality of circumferentially spaced springs 83! (see Fig. 3) that support the sections of the upper wrench 57 in and on the rotatable ring gear 19. As can best be seen by reference to Fig. 3, when the rotatable ring gear 10 is closed, it forms a vertically extending generally tubular central socket 82 in which the wrench 57 is positioned. Because of the construction of the toggle links 61 and teeth I3 and 14 of the wrench 5'! the torque transferred'to the wrench 5! acts also to tightenthe wrench 51 on the pin 26. A substan- .tial portion, of course, of the torque transferred from the rotatable ring gear I0 to the wrench 51 is transferred between the recess 69 and the rocking pin 68 which fits therein. This tends to twist the toggle link 61 in a clockwise direction (Fig. '10) clamping the wrench 51 tightly on the pin 26. The springs BI support the wrench 51 in the rotatable ring gear I0 and allow the wrench 51 to move vertically in the socket 92 as the pin on which the wrench 51 is clamped, moves vertically while it is being threaded downwardly into the box 22.

The above explanation applies only when the wrench 51 is in place as shown in Figs. 2 and to rotate the pin 26 in a clockwise direction, i. e., for tightening the pin 26 in the box 22. When it is desired to disjoint pipes the wrench 51 is lifted vertically out of the socket 82 in the driven ring gear I0, turned over and reinserted into the socket 82, thereby reversing the toggle link 67 so that upon driving the wrench 5'! in a counterclockwise direction the wrench elements will be tightened and the grippers 58 tightly pressed against the exterior of the pin 26 to rotate it in a counterclockwise direction.

In order to provide for the appropriate positioning of the rotatable ring gear I0 and the wrench 51 with respect to the annular guideway 3|, i. e., so that the semi-annular and quadrantlike sections of the three concentric structures lie along the same radial lines, and thus in order to provide that they can be opened as shown in Figs. 2 and 10, the annular ring gear I0 is provided with an index 83 and the annular guideway 3I has a corresponding index 84 which, when in registry, indicate that the sections of the three concentric structures also are in registry.

In order to prevent the two quadrant-like sections I6 and 11 of the rotatable ring gear III from falling out of the two quadrants 33 and 34 of the guideway 3 I when the quadrants are open, spring detent means as indicated in Figs. 11 and 13 are provided and, in the case of the structure of Fig. 13, the detent is combined with the structure of Fig. 12 to prevent the upper clamping means 25 from being opened unless the two indexes 83 and 33 are in registry. Each of the quadrant-like elements 16 and I! has a notch 35 in its upper surface (see Figs. 11, 12 and 13). The notches 85 in the quadrant-like sections I6 and 1! are engaged by rollers 86 carried in the lower ends of spring pressed plungers 8! that are in turn supported by brackets 83 mounted upon the quadrant 33 or 34 as the case might be. Engagement of the rollers 86 in the notches 65 secures the quadrantlike sections 76 and 'I'! in the quadrants '33 and 30; respectively.

In the case of the spring pressed plunger 31 which is mounted in the bracket 83 carried by the quadrant 33 (Fig. 12), a pin 89 extends upwardly through the top of the bracket 86 where it is in line with one end of a short lever 90 pivoted in a pedestal 9I also mounted upon the quadrant 33. The other end of the lever 90 is in line with a pin 92 which slides vertically in a tubular housing 93 secured to the side of the quadrant 33 and which pin has a lower end (see also Fig. 1) that is in line with a hole 94 drilled in a boss 95 formed on the hand lever 42.

Thus when the quadrant-like section I6 of the rotatable annular gear I9 is not lined up in its quadrant 33, and thus the roller 86 is not lowered into the recess 35 but is on the surface of the quadrant-like section I6, the lever 90 is rocked slightly counterclockwise from the position shown 6 inFig. 12 and the pin 92 is forced downwardly into the socket 94, looking the handle 42 in position. It is impossible, therefore, to swing the handle 42 to open the upper clamping means 25 unless the several concentrically located mechanisms are appropriately positioned as indicated by registry of the two indexes 83 and 84 on the rotatable ring gear 10 and annular guideway 3i respectively.

The rotatable annular ring gear I0, by reason of its having two sets of gear teeth 19 and 80, can be rotated by two separate mechanisms, the first of these being the spinning mechanism and the second being the tightening mechanism. The spinning mechanism will first be described.

Spinning mechanism The pin 26, when stabbed into the box 22, is first locked in the upper clamping means 25 and then is spun into the box 22. The spinning action, which consists in high speed rotation of the pin 26, is produced by a pneumatic spinning motor 96 (see Fig. 2) on the shaft of which there is pinned a bevel pinion 91 (see also Figs. 3 and 10). The bevel pinion 91 is meshed with the bevel gear I9 formed on the upper shoulder of the ring gear I0. The spinning motor 96 is reversible and under the control of a hand lever 98 (Figs. 2 and '14) that is secured on the right end of a horizontally extending shaft 99 (Fig. 14) extending through the center of a hollow hydraulic control shaft I00. The shafts 99 and I00 are journalled in bearing blocks I0! erected on the top of the main housing 20 and extending transversely thereto. The hand lever 98 is provided with a depressible locking latch I02 which must be thrust downwardly by the operators thumb in order to disengage a dog (not shown) from a notch I03 (Fig. 16) cut in the edge of a generally cylindrical hand lever guide I94. The center shaft 99 carries a cam I05 at its centermost position, the cam I05 in turn being engaged with appropriate control levers I06 (Fig. 2), not shown in Figs. 14 and 16, for controlling the spinning motor 96. By moving the hand lever 98 in either direction from its neutral position, the spinning motor is connected to pneumatic system to rotate the bevel pinion 91 in one direction or the other thus rotating the ring gear 10 in a corresponding direction so as to spin the pin 26 into or out of the box 22.

In order to prevent the inadvertent energization of the spinning motor 96 when the pin 25 is not properly locked up in the upper clamping means 25, a safety control is inserted in the pneumatic system. This control is illustrated in Fig. 10. A line I01 leads from an air compressor to the interior of a valve chamber I08 where a spring pressed ball valve I99 normally prevents air from flowing into a pneumatic line H0 that leads from the valve chamber I08. A longitudinally slidable rod III is mounted in webs of the main casting 20 with oneend extending into the space between the joining faces of the guideway 3I and quadrant 33. A spring H2 holds the rod forward when the quadrant 33 is not in closed position. The other end of the rod II I is in line with a valve plunger H3 that extends into the valve chamber I08 and which, when moved into the chamber I09, moves the valve I09 away from its seat compressing the spring which normally presses the ball I99 into its socket.

A similar arrangement consisting of a valve chamber H4, a spring pressed ball valve II5, a valve plunger H6 and a spring urged rod I I! is similarly arranged with respect to the quadrant 34, the valve chambers I lit and I it being in series with the lines TU-I and H l and with a line H 8 leading from the chamber I'I l to the spinning motor. Another pneumatic "line We leads to an oilpump drive motornot shown in the drawings, but the connection'of which isindicated"hy'legend in Fig. 10. A third air line 126 Similarly leads to an air line I2! for a signal whistle T22 (see Fig. 6) the purpose for which will later be explained.

Because the valve -chambers flit and l l i are in series between the air compressor and the spinning motor, oil pump driving motor and whistle, none of these three actuating and signalling means can be operated :until the upper clamping means is closed and the inner faces of the quadrants 33 and 36 have pushed the rods I I1 and I ll, compressing their springs, inserting the lungers H3 and I It into the vaI-vechambers Hi8 "and 1M "and opening the valves 'control-led bytheballs IE9 and I'I5.

This interlock between the upper clamping means 25 and the operative elements of awrenoh embodying the invention insures that the wrench will not inadvertently be operated while it is opened since, of course, such operation would mangle the various operative elements of the device.

The spinning motor is used not only 'to spin the pin 26 into the *box 2'2 but also to spin the pin '23 out of the box 22 after it has initially been loosened and to back off the wrench 51' and rotate it the necessary distance to re-ali'gn the indexes iii and $3 4 either after the pin 2 B is tight or after it is completely urithreaded and it is desired to open the upper clamping means 25.

'Comirols for tidhtening mechanism The tightening mechanism which is embodied in a wrench according to the invention consists in apparatus for applying substantially pure torque to the {pin 2:6. The apparatus acts through the ring gear Ill and wrench '51.

The tightening mechanism is controlled by a hand lever I23 (see Figs. 2 and 14-16 particularly) which is secured to the right end of the hollow shaft Hill and provided with a'thumb operated release latch I2 3. The hand lever I23 has five positions, the centermost being the neutral position and .two positions on each side of neutral, the purposes for which and the results at each position to be later explained.

Four control valve actuating cams I25, I 2'6, I21 and L28 are secured on the hollow shaft 188 and engageable with the upper ends of corresponding pins are, HE, IS! and Hirespectively (see Figs. '6--9).

Each of the four cams I25-I28 has two high operating surfaces I33 and I34 (see Fig. 15) which depress the pins I29- I32, respectively, when the cams are appropriately rotated by movement of the hand control lever $23. Each cam also has two low operating surfaces I35 and I35 and a neutral position located centrally of the four operating surfaces. 'In the case of the cam I28, for example (see Fig. 15), the-high surfaces 'I33 and I34 are so spaced that the pin 132 is depressed at the minus 1 and plus 2 positions; the low surfaces 135 and I36 being spaced to permit the pin I32 to remain up at minus 2 and plus 1 positions. The positioning of the high and "low surfaces on the other cam 'I'25-I'21, inelusive-will appear from the following description of the operation of the device in connection with Position of lever 123 Movement Illustrated minus 2 clockwise rotations minus i countercloclnviser' neutral0 none plus 1 s clockwiscl'otatiom. plus 2 counterclockwiserotation.

The hydraulic system by which the movement of the wrench mechanism is controlled operates to control the movement or a pair of actuating rams I37 and its (see figs. 5 and '6) which are linked together at their inner ends Joy being yoked to a'p'in I 39 that extends upwardly and is secured to a heavty arm will oi a wrenchnwinging crank MI. The rams I31 and it?! are given the "designations #1 and #2' in the drawings in order to simplify correlation between figures. Each 'of the rams 137 and I38 is located in a cylinder I42 or its, respectively, which are positioned in a pair of elongated chambers I'M and IE5, respectively (see Fig. 2).

Referring again to Fig. '6, the hydraulic system includes an oil "reservoir we which is connected to an oil pump It? and to an oil return line 148. A hydraulic line W9 connects the oil pump It? to a pressure regulating valve 1'50 that is provided with a pressure indicating gauge I51 and a regulating hand "wheel I52. The line Hi9 leads into a block IE3 or the valve IEil where it intersects a line V541 leading "to "the gauge i5! and a line 1'55 leading to a pressure line 1'56 that is connected with a valve manifold generally indicat-ed at "I57. A spring pressed plunger IE3 is located in 'a sleeve I59 that slides in a bore I60 in the block I53 and acts upon a ball valve IB'I closing a line I62 that also intersects the lines Idii, I54! and I55. A second plunger I53 extends into the bore its and presses on the opposite end oi a spring "I 6 5 which is located in the "sleeve I5'9 andpresses on the plunger F58. The outer end of the plunger FE-3 is radially spaced from the center of the hand wheel I52 the same distance as a plurality of adjustable positioning pads I65 on the hand wheel F5 2. 3y rotating the hand wheel to position a different one of the pads I65 bacl: of the plunger I53, the plunger can be positioned in the sleeve 1 51 to preload thespring led and thus the bail valve 'l't'l for preselected hydraulic pressures at which the ball Valve I61 will open,

I A chamber IE6 inside the block "I 53 and behind the ball valve N51 is in direet communication with the return line M8 to "the oil reservoir M6 when a'piston 'Iii'l that normally blocks the passageway between the chamber F6 6 and "the return line Mil is moved ba'ckwardl'y compressing its spring N58. The piston It! is on the front end gilt alpii sgi rod I69 which extends o'ut-otfthe valve oer 5 and is engaged with th ri' ofthe whistle I22. 9 t p lever no Thus when the pressure of the oil um from the pump it to the pressure line its :33 thence through the valve manifold "i5? to one o f the rams F8?! "or was reaches a "point predeter- 9 mined by the setting of the hand Wheel I 52, and thus, for example, the pin 26 is tightened sufiiciently into the box 22, the ball valve I6I is displaced and hydraulic fluid at the predetermined pressure enter the chamber I66, displacing the piston I61 and flowing immediately into the return line I46 back to the oil reservoir. The oil merely recirculates from pump to reservoir when sufficient hydraulic force has been applied to the ram being used to tighten the pin 26 in the box 22. This occurrence is indicated to the operator because the displacement of the piston I61 by the oil entering the chamber I66 trips the lever I10 and sounds the Whistle I22. At this point the operator moves the hand lever I23 in a manner to be described, stopping the tighteningoperation.

The pressure line I56 leading from the oil pump I41 is connected in the manifold I51 to a pair of leads HI and I12. The lead I1I enters a-valve chamber I13 below a ball valve I14 that is urged upwardly by a spring I15 and which is engaged with the lower end of the pin I30 actuated by the cam I26 on the control shaft I00. The upper portion of the chamber I13 is connected by means of a lead I16 to the lower portion of a second valve chamber I11 which is equipped with a ball check I18 urged upwardly by a spring I19 and in contact with the lower end of the valve pin I29. The lower portion of the chamber I11 also communicates with a main ram lead I88 which is connected to the cylinder I42 of the ram I31, #1.

The upper end of the valve chamber I11 above the ball I10 is connected to a return lead I8I which in turn connects to the return line I48 and to the reservoir I46.

Similarly, the hydraulic lead I12 communicates with the lower end of a valve chamber I82 in which is located a ball check I83 urged upwardly by a spring I84 and controlled by the pin I 3I that is actuated by the cam I21. The upper end of the chamber I82 is connected by a lead I35 to a second chamber I86 having a ball check I81 pressed upwardly by a spring I88 against the lower end of the pin I 32 that is controlled by the cam I28. As is the case with the other valve chambers already described, the chamber I86 is connected below the ball check I81 by a lead I83 to the cylinder I43 in which is located the ram I38, #2. The chamber I86 is connected by a line I60 located above the ball check I61 to the return line I46 and. to the oil reservoir I46.

Referring now to Fig. 9, the mechanism constituting the hydraulic control for the rams #1 and #2 is shown in the position for advancing the ram #2 and rotating the wrench crank MI in a clockwise direction. The hand lever I23 is moved to rotate the shaft I00 to swing the four cams I25, I26, I21 and I28 into positions to depress the pins I23 and I3I, lowering the ball checks I18 and I63, so that oil under pressure flows from the pump line I56 through the valve chamber I82 and beneath the check I81 to the cylinder I43 advancing the ram I38 (#2) in the cylinder I43. At the same time the cam I25, by depressing the pin I29, opens the check I18 and places the cylinder I42 in communication with the return line I48 through the line I80, valve chamber I11 and line I 8|. Oil under pressure thus forces the ram #2, I38, outwardly from its cylinder I43 and oil behind the ram #1,

I31, is allowed to be displaced from the cy1 shaft I00 to swing the wrench MI in a counterclockwise direction. The cams I26 and I28 force the pins I30 and I32, respectively, downwardly to depress the ball check I14 and I01, respectively, establishing connections which are the reverse of those described with reference to Fig. 9. When the lever I23 is set as indicated in Fig. 8, oil under pressure flows from the pump line I56 into the valve chamber I13 past the ball check I14 and through the passageway I16 to the valve chamber I11, then through the lead I into the cylinder I42 to advance the ram #1, I31, and rotate the Wrench crank MI in a countel-clockwise direction. Again, similar to themrangement of Fig. 8, the cam I28, by depressing the pin I32, opens the valve chamber I86 by moving the ball check I61 downwardly and oil is allowed to escape from the cylinder I43 through the line I89, the valve chamber I86 and the line I60 to the return lead I48 and the oil reservoir I46.

The alternate arrangement of the control positioning is designed so that by moving the lever I23 to either of the first positions an operator can precondition the wrench for a full driving stroke. Forexample, if the lever is first moved to position minus 1, ram #1 is extended out of and ram #2 depressed into their respective cylinders I42 and I43, thus moving the rams and the wrench-swinging crank I-iI to the limit of their travel in a counterclockwise direction, preparatory to driving the rotatable wrench 51 and the pin 26 in a clockwise direction. At this point auxiliary valving means to be described r below, operates to change the valve set up and to stop the movement of the rams #1 and #2 and the wrench-swinging crank I4 I, so that when the operator moves the lever I23 to position minus 2, the valving mechanism is reversed to the condition shown in Fig. 9 and the ram #2 extended to rotate the wrench-swinging crank I 4I in a clockwise direction under pressure, tightening the pin 26 in the box 22.

Referring now particularly to Figs. 3, 4, 5,10-14 and 15, it will be observed that the wrench crank I4I has a yoke portion ISI (Figs. 3 and i) which is rotatably mounted in a way I82 in the guideway 3i and which is integral with the heavy arm I 400i the crank MI. The arm hi0 also has outwardly extending finger I63 which mounts a position indicator I94 that is visible through an arcuate window I95 on the front of the main housing 20 and which swings on a horizontal plane. The pin I30 which connects the crank I4I to the rams I31 and I38 extends downwardly through an arcuate slot I96 (Fig. 5) in a web of the main casting 20' and the finger I93 swings horizontall above a horizontal web of the main housing 20 and in line between a pair of downwardly extending pins I91 and I96 (see Fig. 1

The pins I91 and I68 are studded in a pair of blocks I99 mounted on opposite ends of a .tie rod 200 that is in turn pivotally connected to the lower ends of a pair of bell cranks 26I and it is pivotally mounted in an ear 20-1 formed on the upper side of a cover 208 of the main casting 20 and its other arm 266 carries a-small roller 2I0 which rolls on the surface of the associated cam I26. The arm 289 of the lever 206 the'spur gear it on the ring gear Hl "'lh 'paw l thus is operatively interposed between the earn 128 "and" the vertically movable 'p'in i 32 which; actuates' the ball check :31 iri'the valve" cha'nfg b'ei""'I85T "Similarly, an actuating arm of the lever 255 is interposed b'etwe'en the cam i'ZQand'the pin [29 "whiohactuates the 'foall' check {18 the: valvechamber' H'll P Continuing the operation discussion with respectto the movement hy'the operator of the lever !23 to position minus 1; thus establishing the operative conditions illustrated in' land rotating the wrench tightening crank it] a counterclockwise direction by feeding oil "under pressure to the cylinder M2 of the rain #1; whenthe' finger 493 of the" wrench tighten'hg crank Mi strikes the pin 98 (Fig. 14) 'it' hi f ts the tie rod illii'to the right (Fig. 14) rotating the: bell cranli'mif, raising the pin 2133, swinging the lever 21%;" thr'ustin'g'the hall actuating pin" downwardly and "connecting the "valve chamber I T! to its oil return lead 58! Oil under pressure thuscirculates, by-passingthe "ma enta the cylinder M2. for the "rain; #1, and stepping; the counterclockwisemovement offth e wrench crank .v 4. The operator then moves the lever :23 to the position minus 2, to move-the valvesinto'the position illustratedfin 'Fig'; 9-,"drivihg #2 outwardly and rotatingthe wrench erase iii} in a" clockwise direction; The strokeof'th'e piston driving the cranli'i ii is controlled by the engagement between the finger "153' pin H315 (Fig; 14-), in this in nee pulling the tie rod. 2.1313 to the left, swingihe be'll'cr'ahk "2G 5 thrusting the pin Zifll upwardl tlltirig'th'e lefleiY 2% and. depressing thefpin- 132 to depressthe ball. check 58? and cause thepressure oil "th'n' flowing through the valve chamher iilt and-line: I $19. to: the cylinder M3, to he "deflected "and to: flow around the hall check i81- aiidfiutof'the liner N38 to the return line manna theo'il reiser voir '46- r i Similar conditions are encountered and similar operations take place wh'n'th'e "operator swings the lever $23. into positions "plus'l and 'p 2; the rams and wrenoh crank 14! b ng" swung in a clockwise direction"ur itil the'fing lastst-rikesthe pin fist. (mgl'llfto open-cite passageway aroun'dthe ball check It and then, when the operator'moves the lever into mepq'sr: tion plus 2, -setting the controls as illustrated'in Fig. 8; to rotate the "inechanismfih'a"coiiiiter clockwise direction until the limit reached by engagement between the finger I 93-and pin |"9l;'

re c r ve for i mw meshanism.

The wrench crank Ml, the actuation ofwhich in both clockwise and bounterclock' e dire has been described, serves, to rotatethe ringg I Hi throughthe medium of mechanism which ll now be described, The mechanism connect the 'rarn actuatedwrench crank, 15! tothejru gear Hi consists in means for selecti' /Qly engae ingtwo'pa'wls Zll'and 2l2 (Figs. '3 and lilti ith 2H is engaged when it is desired to yota e the ring gear F0 in a couhtercloekwise direc 'on andi the pawl 212 is engaged when it isi'gdes'ired 'toi rotate the ring gear is in a clockwise direc ion Each of I the pawls 2H and 213 isfrocl; g1 mounted upon one of ,a pair of vertica lly ex--,j tending'pins 213 which are studded m theifarin me or the wrench crank, m Each gfthp 2H" and'2I2 "isptovided with"a, compress s g 21.4 en ing t wine the r spe t v pa l li i ds to n a e wit th spu e r it h v 'i e l i- 'A Wed e iii is. mount d b''twn new ti and 3? wi h t si es nt h f l ill'e ,1 en e pawl 21 and *2 e a 1 ?Q Ei 1 -f The W d 2F rockingly mounted upon a vertically extending D 'er n w ich the e i fixedly secured an arm 269 which carries a roller 132i]; on as other end. The roller 22 i; is engaged in an arcuate slot 22 cut on a center coinciding with, at; o e pin ti n an ie enabl control sector 22 2 guided for horizontal recipro; e t m em t we. Pe pins 2% se in bores 2-24; drilled in the arms of the stationary guideway 3| and located on opposite sides oi the rotatable ring gear in v The sector 222 is reciproc -ated horizontally along. a line perpendicular to the path o1" move ment ofthe rains [3-1 and; 3 8- loy mechanism also under the control oft-he hydraulic actuating con,- trol lever l;23 A pair offioell cranks 32-5 (Figs. 3 and 14) are secured to the shaft [0Q near its center and carry a horizontal roller 22% which, extends into" a' yoke 2 21' that is fixed on the upper surface o ffa cylindrical extension 228; of the-sector 222 The roller- Z26 loosely fitsin the yoke 2?}, sufficien-t play being provided so that the roller 226 doesfriot engagethe wings oji the yoke 22-1 when the lever [23? is moved tolposi l tions minus 1- or'plus 1.

At the underneath side of the extension 228;, notches22fl- (Fig. 3) are engageable by a spring pressed (letent 23:3, there being three of the notches 2'2 9- corresponding to: the neutral; l 111111115 Re umes. f e. a tua n lever [23;

When the actuating lever 123; ts mo-ved into minusz position, for exa nple the hell; are Swims nQeI le h is r e t on to movethe sector 2-22; inwardly, (to the left in Figs. 3' and 4 The inward movement of the sector 2 2:2 acting through the; walls of its slot 2 2= 'I m oves'the roller Z'Zfi in ardIy, swingingthe arm 2 9- in a counterclockwise direction (Eig t) and rotating the wedge 2 l5 similarly in a CQullterclockwise "direction-f which swings the corner wa ed 24 a ay. rom. he, hq lder. 1 T fi hs a h pr 2 i4. th s expant and swing-the pawl 2l2fin apountercloclgwisedi rectio n on its pin 2-l:to engage the teethoffthe pawl 2 1 2f wi't h the spur gearfig; on the annular, ring gear 10. i

As earlier explained,- inoyementinto position minus- 2-sets the valving mechanism so-that-oir underp ressure is admitted intoiithe"cylir icler hi3 behind the ram #2 to; swing the wrench cranl M! in a clockwise direction. With thQIJBNVIJZlZ-Q engagedfwith the ring gear 10; theclockwise rotationigof the wrench; era-nip Ifij rotates the ring gear 1 z w sed ree ien n u t tenin the wrench'5fl-on the pin ZG and rotating, the pin] 26in a clockwise direction,

Similarly, when thecontrollever 12-3 is swung; w h 'n v ii plus 2 he. ctor. mfis mov e.

ing tl-ile arxn 2I9' and we-dge 2"i5 in a clockwise. direction removing the shoulder of the wedge, 2 l-5" fro:rn behind "the shoulder 218* of, the pawl; 2 u andallowing its spring 211m swing t pawl 1 2H in'tolthe' engagement with the annular ring,

13 pawl 2 to rotate the annular ring gear 10 in a counterclockwise direction swinging the wrench 51 in a counterclockwise direction and unthreading the pin 26 from the box 22.

Positions minus 1 and plus 1 are designed to permit the operator to retract the mechanism to the limit of its travel before engaging the driving pawls 2II or 2I2 with the ring gear III. Because of the play between the roller 226 and yoke 221, the pawls 2H and 2I2 are not swung inwardly into engagement with the ring gear I until the control lever I23 is moved to either minus 2 or plus 2 position.

The following table correlates the positions of the control lever I23 and valve actuation with the actuation of the rams #1 and #2? and resulting movement of the wrench crank Ml and pawls 2H and 2I2 to rotate the ring gear ill and the pin 26:

14) and the operator can at any time observe the relative position of the wrench crank MI by viewing its indicator I94 through the arcuate window I95 in the front of the housing 20.

Thus, if an operator is assembling a long string of drilling pipe or casing elements, he stabs a pin into a box, locks the upper clamping means to clamp the pin in the wrench 51, spins the pin 26 into the box 22 through the medium of the spinning motor under the control of the hand lever 98, and, when the pin is substantially tightened in the box, moves the control lever I23 between the positions minus 1 and minus 2 to apply successive driving strokes to the wrench tightening crank IM and to the pin 26 until it is tightened in the box 22 with a force sufiicient that the hydraulic pressure in the pressure side of the hydraulic system reaches a. point where it displaces the safety ball check IBI of the pressure valve mechanism,

TABLE II Valve Pin Settings Position of Control Ram 3323a 62333: awl e 7 g Lever 123 Advanced Engaged and Pin 26 c. =clockwise. cc. =counterclockwise.

From Table II it can be determined that the cams I25, I26 and I2! are designed similarly to the cam I28 but with their high and low operating surfaces placed to depress or to allow the pins I29-I32 to move up as indicated.

In addition to the four valve operating cams I25-I28 and the cranks 225, the hollow shaft I00 also carries an oil pump control cam 23I (Figs. 14 and 16) which controls the operation of the oil pump I41 when the operating lever I23 is moved into any one of the four operating positions.

Whether the rams #1 and #2 (I31 and I38 respectively) are being used to move the wrench crank ml to the end of its stroke preparatory to rotating the ring gear I9, 1. e., with the control lever I23 in the positions minus 1 or plus 1; or whether the rams #1 and #2 are being employed to actually rotate the ring gear I0 and thus to rotate the pin 26, i. e., with the control lever I23 in positions plus 2 or minus 2, the stroke limiting mechanism consisting of the pins I91 and I98 (Fig. 14) operates to stop the movement of the Wrench MI at the limit of the stroke of the driving one of the rams l and #2.

After the operator has moved the control lever I23 into position plus 2 or position minus 2 as the case might be, and after an operating stroke has been delivered by the ring gear I0 and wrench 51 to the pin 26, it is necessary to disengage that one of the driving pawls 2 or 2I2 from the ring gear I0 and to return the mechanism to the other end of the stroke of the rams I37 and I38. The operator accomplishes this movement by, for example, swinging the lever from position minus 2 in which it has been placed to drive the gear I9 and pin 28 in a clockwise or tightening direction, to the position minus 1. As can'be seen from Table 11 above this reverses the valving mechanism, disengages the pawl 2 I2 and returns the wrench crank MI in a counterclockwise direction to the end of its stroke. Arrival at the end of the stroke in a counterclockwise direction is signalled by the operation of the limiting mechanism involving the pins I91 and I98 (Fig.

stops the tightening action and blows the signal whistle I22.

At this point the operator moves the control lever I23 into position minus 1 to return the wrench crank I4I to center with the pawls 2H and 2 I 2- disengaged and then, reversing the spinning motor 96 drives the ring gear 10 in a counterclockwise direction to slack off the wrench 51 until the index 83 coincides with the index 84 on the annular guideway 3 I. The operator can then open the upper clamping means 25 and the lower clamping means 2I, lower the coupled string into the well and reset the lower clamping means 2I on the box end of the last coupled pipe section. He then stabs in a new pin 26 and repeats the operation.

Diassembly of a stringof pipe involves the reverse of these steps outlined above with the hydraulically operated wrench crank I4I being first employed to loosen or break the joint between the pin 26 and box 22 being disassembled and the spinning motor 96 then being employed in reverse to spin the pin out of the box 22.

While the invention has been disclosed in conjunction with a specific form of the parts, various modifications and changes will suggest themselves to those skilled in the art, and it should be expressly understood that such modifications may be made within the scope of the invention as dehaving a peripheral gear, said second power; driven means comprisinga reciprocal drive element and a pai of toothed; power transfer? means driventherebx and alternatively engageable with; said peripheral gear;

2. A power tongs, mechanism; for assemblin and disassembling lengths; ofi pipecomprising', in combination, clamping: means for holding; standing length of, pipehaving; a joint element, a rotatable wrencha for grasping and; rotating; an, upper length at pipe having a mating joint element, means comprising; an openable' clam-p for securing such upper pipe; in said, wrench, firstv power means. for rotating said: wrench at high speed; and second. power driven meansior' 10,113.12? i-ng said wrench with high, torque; said: wrench having a peripheral gear, said. second power driven: means comprising; a reciprocak drive element, an oscillatable wrench crank, actuated thereby, and a pair ot toothed power transfermeans mounted. on said: crank; and alternatively engageable with said peripheral gear,

3. In a power tongs mechanism according to claim 2 the improvement consisting in toothed power transfer meansv having arcuatez toothed sections of more than; one: tooth, andengageabl'e with said peripheral gear.v

4. In a wrench mechanism of the class described a rotatable. pipe grasping wrench; aperipheral gear on said wrench,v an. oscillatable wrench crank, a pair oi alternatively-engageable pawl means on said crank for drivingly engaging said gear, hydraulic means for oscillating said crank and a single control for said hydraulic means and said pawtmeanswhereby saidcranir is:

selectively oscillatable when neither ots-a id pawl means is: engaged and said cranlc is selectively oscillat'ahle in either direction when a cor-re spending one oii said paavl means is: engaged.

5. A mechanism according to claimi -i11 which said contro-l means-1 has a: neutral position: in which neither of said paw-ls is engaged; a pair of-= oppositefirst posit-ions iii-which said hydra'ulic means is connected toswing said crank, and a pair of: second positions irrw-hi'ch said: hydraulic means isconnecteduto swing said 'cranle and. in

eachof which second positions cne oi said paw-1's is engaged; for rotating said wrench:

6= Control and drive mechanismfor a pipetongs having a rotatable wrench with a. periphr eral gear; and cosaxial wrench swinging: crank having a pair of pawl'a alternatively engageable with-said gear; said mechanism:comprising'apair of opposed hyd raulicrams linked: tousaid wrench, a source of fiuid under-pressure, valve means for selectively connecting said source to.- saidirams,

a single control -lever foraotuating said valve means, and linhageconnecting said? lever to: said pawls for alternati'vel-y engaging one ,ofisaidipawl's' with said gear.

7. Control and drivemechanism according to;

claim 6 in which said leverhasa neutral: pOSition, a first position on each side of="neutraltin.

which the valve means are actuat'edl to drive one of the rams for swinging the wrench crank in thec(fir-respondingdirection: andla .seoondposition on each" sideioi neutral-in which said valve means are actuated for swinging. said: crank-1 in. a; direction opposite: tothat; of the adjacent; first;

position and inwhich second position. the linksage isactuated to engage thecorresponding one" and two; quadrant; sections pivotally connected;

theretm said; sections having, an inner; annular.

1 0; Power; drivenv tongs. iior assembling, and-dis? assembling lengths or; similar material, said tongs comprising, in combination, a rotate ableopenable wrench, removable annular gripper means carried by said wrench and. adapted-1w grip the exterior of a length of pipe to be rotated, said gripper means being reversible to apply gripping force in a desired direction of rotation and to relax gripping force when. rotated. oppositely therefrom, pneumatically actuated means including a direct gear drive to said wrench for rotating the same at high speed, a hydraulic system includinghydraulically actuated means for rotating said wrench athigh torque and: in,-

clucling multiple tooth; alternately engageablev driving pawls, teeth on the exterior of said wrench engageable by said pawls, a, pneumatically actuated pump for creating hydraulic force in" said system, control means for selectively applying forceto saidwrench and for engaging one of said pawls for thet'r-ansznit'tal thereof tosaid wrench, and a safety disablingmechanism operable when said wrench is openfor preventing the'actuat-ion of both saidpneumatically actuated means including the direct driveand said pump.

11. Power driven tongs according to claim 10 in which the hydraulic system" includes a pair of parallel valving systems, opposed hydraulic rams for actuating said means for rotating said wrench, a:- single control lever for said valying systems; each of said vaiving systems including a drive valve a lay-pass valve, and a by pass: val'veinsaid system operable at a selected pressure whereby said rams are driven with amaximum force for tightening the pipeto only aselected degree.

12.- Power' driven tongs accordingto claim 10 in which the hydraulically actuated means for rotating thewrench at high torque consists in-a wrench crank oscillatable about an axis com-- men with said" wrench, said crank serving to mount saiclpair of multiple tooth p'awls alternatively engageabie with the teeth on said wrench, a pair of opposedhydraulic rams driv-= ingly= connected to said crank, valve mean's'for controlling theactuationof said' rams, linkage fol-alternativelyengaging saidpawls; said con-- trol means controlling both saiol valve" means and said linkage and limit means actuated bysaid crank at the ends of itsstroke for over controlling said control.

FRED E. SMITH;

liteferences. Cited. in; the the of this patent UNITED STATES PATENTS- Number. 7 Name Date 2', i,5l;l',,)3sl-v Calhoun 00.12;,1211948 2, 53,369; Grabl'eret' al., Nov. 9;,19'483 2566993 Stone Sept..4,'.1951 

